75102-74-8

Usage

Uses

Used in Medicinal Chemistry:
7-Chloro-D-tryptophan is used as a key intermediate in the synthesis of peptide-based drugs, contributing to the development of novel therapeutic agents with improved pharmacological properties.
Used in Biochemical Research:
As a building block, 7-Chloro-D-tryptophan is utilized in the production of new chemical entities, facilitating the exploration of its unique structure and properties for potential applications in biochemical research.
Used in Organic Chemistry:
7-Chloro-D-tryptophan serves as an interesting target for research and development in organic chemistry, due to its distinct structural features and the possibility of its involvement in the creation of innovative organic compounds.

Upstream product

• 53924-05-3 7-chloro-1H-indole 
• 77290-47-2 N-Acetyl-7-chlor-DL-tryptophan 
• 73-22-3 L-Tryptophan 
• 312-84-5 D-Serine 
• 153-94-6 D-tryptophan 
• 56-45-1 L-serin 
• 77290-46-1 2-Acetylamino-2-{3-[(2-chloro-phenyl)-hydrazono]-propyl}-malonic acid dimethyl ester 
• 77306-52-6 2-Acetamino-2-(7-chlor-3-indolylmethyl)malonsaeure-dimethylester 
• 153-97-9 7-chloro-D/L-tryptophan 
• 77290-48-3 7-Chlor-N-chloracetyl-D-tryptophan 
• 852391-55-0 (S)-N-acetyl-7'-chlorotryptophan 
• 77290-48-3 7-Chlor-N-chloracetyl-DL-tryptophan 
• 77290-45-0 2-Acetamino-2-(2-formylethyl)malonsaeure-dimethylester 

Downstream Products

• 1079926-41-2 7-phenyl-L-tryptophan 
• 852391-20-9 (R)-5-((7-chloro-1H-indol-3-yl)methyl)-3-methylimidazolidine-2,4-dione 
• 3804-16-8 2-(7-chloro-1H-indol-3-yl)ethanamine 
• 852391-20-9 (S)-5-(7'-Chloro-1H-indol-3ylmethyl)-3-methyl-imidazolidine-2,4-dione 

Relevant academic research and scientific papers

Tuning the Biological Activity of RGD Peptides with Halotryptophans ?

An array of l- and d-halotryptophans with different substituents at the indole moiety was synthesized employing either enzymatic halogenation by halogenases or incorporation of haloindoles using tryptophan synthase. Introduction of these Trp derivatives into RGD peptides as a benchmark system was performed to investigate their influence on bioactivity. Halotryptophan-containing RGD peptides display increased affinity toward integrin αvβ3 and enhanced selectivity over integrin α5β1. In addition, bromotryptophan was exploited as a platform for late-stage diversification by Suzuki-Miyaura cross-coupling (SMC), resulting in new-to-nature biaryl motifs. These peptides show enhanced affinity toward αvβ3, good affinity to αvβ8, and remarkable selectivity over α5β1 and αIIbβ3 while featuring fluorogenic properties. Their feasibility as a probe was demonstrated in vitro. Extensive molecular dynamics simulations were undertaken to elucidate NMR and high-performance liquid chromatography (HPLC) data for these late-stage diversified cyclic RGD peptides and to further characterize their conformational preferences.

Straightforward Regeneration of Reduced Flavin Adenine Dinucleotide Required for Enzymatic Tryptophan Halogenation

Flavin-dependent halogenases are known to regioselectively introduce halide substituents into aromatic moieties, for example, the indole ring of tryptophan. The process requires halide salts and oxygen instead of molecular halogen in the chemical halogena

One-Pot Biocatalytic Synthesis of Substituted d -Tryptophans from Indoles Enabled by an Engineered Aminotransferase

d-Tryptophan and its derivatives are important precursors of a wide range of indole-containing pharmaceuticals and natural products. Here, we developed a one-pot biocatalytic process enabling the synthesis of d-tryptophans from indoles in good yields and high enantiomeric excess (91% to >99%). Our method couples the synthesis of l-tryptophans catalyzed by Salmonella enterica tryptophan synthase with a stereoinversion cascade mediated by Proteus myxofaciens l-amino acid deaminase and an aminotransferase variant that we engineered to display native-like activity toward d-tryptophan. Our process is applicable to preparative-scale synthesis of a broad range of d-tryptophan derivatives containing electron-donating or -withdrawing substituents at all benzene-ring positions on the indole group.

Dynamic Kinetic Resolution for Asymmetric Synthesis of L-Noncanonical Amino Acids from D-Ser Using Tryptophan Synthase and Alanine Racemase

L-Ser is often used to synthesize some significant l-noncanonical α-amino acids(l-ncAAs), which are the prevalent intermediates and precursors for functional synthetic compounds. In this study, threonine aldolase from Escherichia coli k-12 MG1655 has been used to synthesize l-Ser. In contrast to the maximum catalytic capacity (20 g/L) for l-threonine aldolase(LTA), d-Ser was synthesized with high yield (240 g/L) from cheap Gly and paraformaldehyde using d-threonine aldolase (DTA) from Arthrobacter sp ATCC. In order to fully utilize d-Ser and expand the resource of l-Ser, a dynamic kinetic resolution system was constructed to convert d/dl-Ser to l-Ser through combining alanine racemase (Alr) from Bacillus subtilis with l-tryptophan synthase (TrpS) from Escherichia coli k-12 MG1655, and l-ncAAs including l-Trp and l-Cys derivatives were synthesized with excellent enantioselectivity and in high yields. The results indicated l-ncAAs could be efficiently synthesized from d-Ser using this original and green dynamic kinetic resolution system, and the reliable l-Ser resource has been established from simple and achiral substrates.

Structure-based switch of regioselectivity in the flavin-dependent tryptophan 6-halogenase Thal

Flavin-dependent halogenases increasingly attract attention as biocatalysts in organic synthesis, facilitating environmentally friendly halogenation strategies that require only FADH2, oxygen, and halide salts. Different flavin-dependent tryptophan halogenases regioselectively chlorinate or brominate tryptophan’s indole moiety at C5, C6, or C7. Here, we present the first substrate-bound structure of a tryptophan 6-halogenase, namely Thal, also known as ThdH, from the bacterium Streptomyces albogriseolus at 2.55 ? resolution. The structure revealed that the C6 of tryptophan is positioned next to the -amino group of a conserved lysine, confirming the hypothesis that proximity to the catalytic residue determines the site of electro-philic aromatic substitution. Although Thal is more similar in sequence and structure to the tryptophan 7-halogenase RebH than to the tryptophan 5-halogenase PyrH, the indole binding pose in the Thal active site more closely resembled that of PyrH than that of RebH. The difference in indole orientation between Thal and RebH appeared to be largely governed by residues positioning the Trp backbone atoms. The sequences of Thal and RebH lining the substrate binding site differ in only few residues. Therefore, we exchanged five amino acids in the Thal active site with the corresponding counterparts in RebH, generating the quintuple variant Thal-RebH5. Overall conversion of L-Trp by the Thal-RebH5 variant resembled that of WT Thal, but its regioselectivity of chlorination and bromination was almost completely switched from C6 to C7 as in RebH. We conclude that structure-based protein engineering with targeted substitution of a few residues is an efficient approach to tailoring flavin-dependent halogenases.

Aromatic Halogenation by Using Bifunctional Flavin Reductase–Halogenase Fusion Enzymes

The remarkable site selectivity and broad substrate scope of flavin-dependent halogenases (FDHs) has led to much interest in their potential as biocatalysts. Multiple engineering efforts have demonstrated that FDHs can be tuned for non-native substrate scope and site selectivity. FDHs have also proven useful as in vivo biocatalysts and have been successfully incorporated into biosynthetic pathways to build new chlorinated aromatic compounds in several heterologous organisms. In both cases, reduced flavin cofactor, usually supplied by a separate flavin reductase (FR), is required. Herein, we report functional synthetic, fused FDH-FR proteins containing various FDHs and FRs joined by different linkers. We show that FDH-FR fusion proteins can increase product titers compared to the individual components for in vivo biocatalysis in Escherichia coli.

Unlocking Reactivity of TrpB: A General Biocatalytic Platform for Synthesis of Tryptophan Analogues

Derivatives of the amino acid tryptophan (Trp) serve as precursors for the chemical and biological synthesis of complex molecules with a wide range of biological properties. Trp analogues are also valuable as building blocks for medicinal chemistry and as tools for chemical biology. While the enantioselective synthesis of Trp analogues is often lengthy and requires the use of protecting groups, enzymes have the potential to synthesize such products in fewer steps and with the pristine chemo- and stereoselectivity that is a hallmark of biocatalysis. The enzyme TrpB is especially attractive because it can form Trp analogues directly from serine (Ser) and the corresponding indole analogue. However, many potentially useful substrates, including bulky or electron-deficient indoles, are poorly accepted. We have applied directed evolution to TrpB from Pyrococcus furiosus and Thermotoga maritima to generate a suite of catalysts for the synthesis of previously intractable Trp analogues. For the most challenging substrates, such as nitroindoles, the key to improving activity lay in the mutation of a universally conserved and mechanistically important residue, E104. The new catalysts express at high levels (>200 mg/L of Escherichia coli culture) and can be purified by heat treatment; they can operate up to 75 °C (where solubility is enhanced) and can synthesize enantiopure Trp analogues substituted at the 4-, 5-, 6-, and 7-positions, using Ser and readily available indole analogues as starting materials. Spectroscopic analysis shows that many of the activating mutations suppress the decomposition of the active electrophilic intermediate, an amino-acrylate, which AIDS in unlocking the synthetic potential of TrpB.

Extending the biocatalytic scope of regiocomplementary flavin-dependent halogenase enzymes

Flavin-dependent halogenases are potentially valuable biocatalysts for the regioselective halogenation of aromatic compounds. These enzymes, utilising benign inorganic halides, offer potential advantages over traditional non-enzymatic halogenation chemistry that often lacks regiocontrol and requires deleterious reagents. Here we extend the biocatalytic repertoire of the tryptophan halogenases, demonstrating how these enzymes can halogenate a range of alternative aryl substrates. Using structure guided mutagenesis we also show that it is possible to alter the regioselectivity as well as increase the activity of the halogenases with non-native substrates including anthranilic acid; an important intermediate in the synthesis and biosynthesis of pharmaceuticals and other valuable products. This journal is

Improving the stability and catalyst lifetime of the halogenase RebH by directed evolution

We previously reported that the halogenase RebH catalyzes selective halogenation of several heterocycles and carbocycles, but product yields were limited by enzyme instability. Here, we use directed evolution to engineer an RebH variant, 3-LR, with a Topt over 5-°C higher than that of wild-type, and 3-LSR, with a Tm 18-°C higher than that of wild-type. These enzymes provided significantly improved conversion (up to fourfold) for halogenation of tryptophan and several non-natural substrates. This initial evolution of RebH not only provides improved enzymes for immediate synthetic applications, but also establishes a robust protocol for further halogenase evolution. Evolving halos: We have used directed evolution to engineer an RebH halogenase variant with a Topt more than 5-°C higher than that of wild-type RebH, and a second variant with a Tm 18-°C higher. These enzymes provided significantly improved conversion for halogenation of tryptophan and several non-natural substrates.

Regioselective enzymatic halogenation of substituted tryptophan derivatives using the FAD-dependent halogenase RebH

Regioselective methods to establish carbon-halide bonds are still rare, although halogenation is considered as a commonly used methodology for the functionalization of organic compounds. The incorporation of halogen substituents by organic synthesis usually requires hazardous conditions, shows poor regioselectivity and results in the formation of unwanted byproducts. In addition, halogenation by electrophilic aromatic substitution (SEAr) obeys distinct rules depending on electron-withdrawing or -donating groups already present in the aromatic ring. We employed the tryptophan-7-halogenase RebH for regioselective enzymatic halogenation to overcome these limitations. In combination with a tryptophan synthase, an array of C5- and C6-substituted tryptophan derivatives was synthesized and halogenated by RebH. The halogenase is able override these directing effects and halogenates at the electronically unfavored C7-meta-position, even in presence of ortho/para-directing groups. No business as usual: The tryptophan halogenase RebH from Lechevalieria aerocolonigenes is able to halogenate at the electronically unfavored C7-meta-position of C5-substituted tryptophan derivatives, even in presence of deactivating ortho/para-directing groups.